Gramicidin S (GS) is a nonribosomally synthesized decapeptide from Aneurinibacillus migulanus. Its pronounced antibiotic activity is attributed to amphiphilic structure and enables GS interaction with bacterial membranes. Despite its medical use for over 70 years, the peptide-lipid interactions of GS and its molecular mechanism of action are still not fully understood. Therefore, a comprehensive structural analysis of isotope-labeled GS needs to be performed in its biologically relevant membranebound state, using advanced solid-state nuclear magnetic resonance (NMR) spectroscopy. Here, we describe an efficient method for producing the uniformly 13 C/ 15 N-labeled peptide in a minimal medium supplemented by selected amino acids. As GS is an intracellular product of A. migulanus, we characterized the producer strain DSM 5759 (rough-convex phenotype) and examined its biosynthetic activity in terms of absolute and biomass-dependent peptide accumulation. We found that the addition of either arginine or ornithine increases the yield only at very high supplementing concentrations (1% and 0.4%, respectively) of these expensive 13 C/ 15 N-labeled amino acids. The most cost-effective production of 13 (Fig. 1A). Since its discovery about 70 years ago, GS has been used as a topical antibiotic in Russia and neighboring countries, exploiting its pronounced antimicrobial activity against Gram-positive bacteria (1, 2). For example, GS is the bioactive agent in GrammidinNeo, the lozenge against sore throat and mouth ulcer produced by the Russian JSC Valenta Pharmaceuticals. Notably, despite a long medication history, no clinical cases of bacterial resistance against GS have been reported, which suggest that this peptide may be an exceptionally promising resistance-free antibiotic (3).The biological activity of GS was first described as membranolytic, which is believed to determine its profound antimicrobial as well as hemolytic activities in vitro. Less acknowledged are GS activities not directly related to interaction with membrane bilayers: the peptide has been shown to inhibit membrane enzymes, such as bacterial NADH dehydrogenase and cytochrome bd terminal oxidase (4), and to delocalize the peripheral cell division regulator MinD, the lipid II biosynthesis protein MurG, and cytochrome c (5).The main molecular target of GS is supposed to be the plasma membrane of susceptible bacterial species, where an accumulation of the amphiphilic peptide leads to a loss of the barrier function and an irreversible increase in permeability for ions and metabolites (6). This concentration-dependent effect leads to membrane depolarization (7) and an overall dysfunction of the cellular osmoregulation, which starts already at GS levels well below the respective MICs (8). However, the structure-function relationship of the peptide and its detailed molecular mechanism of action at the plasma membrane, i.e., its interaction with the lipid bilayer, are still lacking a consensus view.Over the last decades, the molecular structure of GS has been stud...
